1.131. Superporous Hydrogels for Drug Delivery SystemsH Omidian, Nova Southeastern University, Fort Lauderdale, FL, USAK Park, Purdue University, West Lafayette, IN, USA
ã 2011 Elsevier Ltd. All rights reserved.
1.131.1. Introduction 5631.131.2. Hydrogels in Drug Delivery 5641.131.3. Superporous Hydrogels 5641.131.4. SPH Synthesis 5651.131.5. SPH Properties 5651.131.5.1. Swelling Capacity 5651.131.5.2. Swelling Rate 5661.131.5.3. Mechanical Strength 5661.131.6. SPH Generations 5661.131.6.1. The First SPH Generation 5671.131.6.2. The Second SPH Generation 5671.131.6.3. The Third SPH Generation 5671.131.6.4. Research on SPHs 5681.131.7. SPH Scale Up 5691.131.8. SPH Stability 5701.131.8.1. SPH Identity 5701.131.8.2. SPH Purity 5701.131.8.3. SPH Potency 5711.131.9. SPH Safety 5711.131.10. SPH Platform Design for Drug Delivery 5711.131.11. SPH in Drug Delivery and Other Areas 5721.131.11.1. Gastric Retention 5721.131.11.2. Peroral Intestinal Delivery 5741.131.11.3. SPHs as Diet Aid 5741.131.11.4. SPHs as Superdisintegrant 5741.131.11.5. Other Applications 5741.131.12. Conclusions 575References 575
Abbreviationsaq Aqueous
CD Circular dichroism
CMC Carboxymethylcellulose
CSPHs Conventional superporous hydrogels
DDS Drug delivery system
DSC Differential scanning calorimetry
EDX Energy-dispersive X-ray spectroscopy
FDA Food and Drug Administration
FTIR Fourier transform infrared
HEMA Hydroxyethyl methacrylate
HPMC Hydroxypropyl methylcellulose
NIPAM N-isopropyl acrylamide
NMR Nuclear magnetic resonance
PEG Polyethylene glycol
PVP Poly(vinyl pyrrolidone)
s Solid
SEM Scanning electron microscope
SPH Superporous hydrogel
SPHCs Superporous hydrogel composites
SPHHs Superporous hydrogel hybrids
TGA Thermogravimetric analysis
UV/VIS Ultraviolet/visible
1.131.1. Introduction
Regardless of the payload (drug, solvent, fertilizer, pesticide,
etc.), a delivery system should possess two major tools to
function. It should accommodate the payload and release
it later on at a controlled rate. Novel delivery systems possess
an extra tool to deliver the load to a desirable site, and are
intended for targeting delivery. Hydrogels have long been
known for their ability to house drugs and to prevent drug
release by a simple diffusion process. Due to their long poly-
meric chains, they provide a physical barrier to drug transport,
as a result of which a drug needs to take a longer path to
563
50mm
Figure 1 A typical superporous hydrogel with an average poresize of 50mm.
Surface
564 Polymers
diffuse out of the delivery system. The barrier properties of the
polymer chains become more significant when the chains are
hydrated in an aqueous medium. Although these features are
attractive in controlled drug delivery, some applications
require a faster transport kinetic. The presence of pores within
a hydrogel structure, through which the drug can be released at
a faster rate, adds another dimension to the transport process.
Pores inside a hydrogel structure are generally closed,
although populated. Porous hydrogels in general have a closed
pore structure, with no well-tailored size or distribution. Super-
porous hydrogels (SPHs), on the other hand, are hydrogels
with an interconnected structure with a relatively narrow pore
size and distribution. The predecessor of SPHs, that is, super-
absorbent polymers, are for instance found in ultrathin or
ultra-absorbent baby diapers and feminine incontinence pro-
ducts due to their outstanding urine or blood absorption capa-
bility. These are made of a very hydrophilic but cross-linked
structure (mostly based on acrylic acid and its sodium salt)
with the ability to absorb 500–1000 g g�1 of distilled water and
40–70 g g�1 of saline (an aqueous solution containing 0.9wt%
sodium chloride). These structures are very sensitive to pH,
nonsolvents, and ionic strength of the swelling medium.
Since this product is supplied in granule and particle form, its
swelling rate can be adjusted by the particle size, which signifi-
cantly affects the particle surface area and hence its absorption
ability. In other words, the larger particles absorb aqueous fluids
at a slower rate than their smaller counterparts. Superporous
hydrogels with the same swelling capacity, on the other hand,
absorb aqueous fluids at almost the same rate, irrespective of
their size in a dry state. Increased surface area in superporous
hydrogels is provided by pores inside their structure. With an
increase in their pore content and decrease in pore size, more
hydrogel surface would be exposed to the swelling environment,
which makes the swelling kinetic faster.
Bulk
1m
m
Figure 2 A three-dimensional porous structure of a typicalsuperporous hydrogel.
1.131.2. Hydrogels in Drug Delivery
There are more than 100 prescription drugs in the US market,
in which one excipient is commonly used, that is, hydroxypro-
pyl methylcellulose (HPMC). Although this polymer is water
soluble, it provides gelling properties when exposed to an
aqueous environment. HPMC with different degrees of substi-
tutions is used in tablet form to control the release of the drug
over a longer period of time. Apparently, there are two features
that enable the HPMC to function as a controlled delivery
system. First, it is very hydrophilic due to its hydroxypropyl
contents. Second, the HPMC chains are in a very compressed
form in a tablet, which prevents them from a fast dissolution in
the aqueous environment. These two features provide gelling
properties such as those found in a chemically cross-linked
hydrogel. Although there is no chemical cross-linker in the
HPMC structure, the applied pressure during tablet prepara-
tion supplies enough entanglement and barrier for the retarded
dissolution of the polymer.
1.131.3. Superporous Hydrogels
A superporous hydrogel is a composite polymer made of a
solid hydrogel and air. The SPH is a unique class of porous
hydrogels with an average pore size of 50–100 mm (Figure 1)
and an interconnected pore structure (Figure 2).1 As its pores
are open, the fluid can travel in a three-dimensional path,
as a result of which the swelling rate of a typical SPH
becomes independent of the SPH size in its dry state.2 While
in nonporous hydrogels the solid part is responsible for the
swelling and mechanical property, the air portion of the SPH
structure plays a vital role in determining the final SPH prop-
erties. Generally speaking, properties such as density, swelling
capacity, and mechanical strength are improved by solid
content, while the swelling rate increases as the SPH air con-
tent increases. The pore content, size, morphology, and iso-
tropicity are all pore features of the SPH, which could
potentially affect SPH stability and function to a lesser or
greater extent.
Composite agent (s)
Hybrid agent (aq)
Foaming aid (aq)Foaming agent (s)
Foam stabilizer (aq)
Oxidant (aq)
Reductant (aq)
Ionogelation Washing anddehydration
Alcohol(aq)
Ion(aq)
Synthesis
Crosslinker (aq)
Monomer (aq)
Figure 3 Synthesis, treatment, and purification of a typical superporous hydrogel.
Reactionmix
Carbonateaddition
Inductionperiod
Foamrise
SPH
Figure 4 Steps in producing a superporous hydrogel foam.
Superporous Hydrogels for Drug Delivery Systems 565
1.131.4. SPH Synthesis
In the preparation of SPHs, a bicarbonate foaming agent is
used, which is water soluble and becomes active in an acidic
aqueous medium. So a solution polymerization is a preferred
method of SPH synthesis. Aqueous solutions of monomer,
cross-linker, foam stabilizer, and foaming aid are added in
turn to the reacting mixture under very mild mixing. Following
a complete homogenization, the reductant and oxidant are
added consecutively and are mixed quickly with the reacting
mixture. In a very short period of time, the solid foaming agent
(e.g., bicarbonate) is effectively dispersed and mixed through-
out the reacting solution. The bicarbonate reacts with the
foaming aid (e.g., an organic acid) to generate carbon dioxide
gases; this reaction in turn increases the pH of the reacting
solution, which favors the decomposition of the initiator.
Due to the retarding effect of the oxygen, there is an induction,
or lag period, which is followed by a fast exothermic polymeri-
zation reaction.3 The foaming and gelling reactions occur
almost simultaneously and proceed to their maximum extent
at the polymerization temperature, which is determined by the
type of monomer, its concentration in the solution, and initia-
tor concentration. A successful SPH is synthesized if the chem-
ical gelation and physical foaming happen in a synchronized
way.4,5 The formation of the SPH foam requires the CO2 gases
to be entrapped within the hydrogel matrix, and this would be
possible if the reacting hydrogel mass reaches a certain viscos-
ity, mf. The foaming viscosity is determined by the rate at which
the gelling reaction happens. At viscosities well below and
beyond the mf, the efficiency of the foaming process would be
decreased significantly and no SPH would actually be formed.
With no increase in the foam height and no increase in the
reaction temperature, both gelling and foaming reactions are
slowed down and the SPH foam is then relaxed for further
treatment, purification, and drying. The overall procedure of
SPH synthesis is shown in Figures 3 and 4 (see Chapter 1.121,
Polymer Fundamentals: Polymer Synthesis).
1.131.5. SPH Properties
1.131.5.1. Swelling Capacity
Swelling capacity in hydrogels and SPH polymers in particular
is defined by the structural hunger for an aqueous fluid. Appar-
ently, the more hydrophilic the structure of the hydrogel, the
stronger the intermolecular interactions that can be built by
the hydrogel with its surrounding aqueous medium. A stronger
polymer–water interaction would be established if the hydro-
gel structure contains ionizable groups such as carboxyl or its
salt derivatives such as potassium or sodium carboxylate. These
hydrophilic and ionic functional groups are responsible for the
polymer–water interaction, electrostatic forces, and osmotic
forces, which are the driving forces for the swelling process to
occur. By far the most important consideration in hydrogel
566 Polymers
swelling is the status of water with respect to the hydrogel core.
Like the electronic layers surrounding the nucleus of an atom,
several layers of water are built up around the hydrophilic and
ionic groups. An electron is separated with more ease in the
presence of electron-loving atoms if it is located in the outer-
most electronic layers. Likewise, water molecules within the
hydrogel located at the outermost layers, far from the hydro-
philic or ionic groups, can be separated with ease. As a result,
the status of water in hydrogels is generally defined as free and
bound water, which reflects the extent of polymer and water
interaction within a hydrogel.
Swelling capacity in hydrogels is generally measured under
free and loaded conditions. A hydrogel is simply placed
in water or an aqueous solution with a little or no pressure
applied on the hydrogel. The hydrogel begins the process of
water absorption via its functional groups and continues to
absorb water until all the functional groups receive the same
amount of water. The amount of water absorbed can simply be
calculated by measuring the hydrogel weight before and after
the swelling.
1.131.5.2. Swelling Rate
The rate at which water or an aqueous medium is absorbed
into the hydrogel structure depends on the hydrogel’s chemical
and physical structure. As far as the chemistry is concerned, the
hydrogels containing more hydrophilic and ionic groups offer
a faster swelling process. At the same chemical composition,
hydrogels small in size or thin (film), and having a porous
structure, can swell faster in an aqueous medium than nonpo-
rous, large in size, and thick (sheet) hydrogels. A nonporous
hydrogel structure absorbs water at its surface layer by layer.
In other words, the water is absorbed into the structure of such
hydrogels following a two-dimensional path. Then, the first
partially swollen layer acts as a water reservoir for the lower
layers. With a porous structure, on the other hand, the whole
hydrogel mass could have the same access to the water, and
hence water can penetrate into the hydrogel structure follow-
ing a three-dimensional path. To measure the swelling rate or
the swelling kinetic, the amount of water absorbed into the
hydrogel structure is measured versus time. While the amount
of water absorbed at times zero and infinite reflect the weight
of the hydrogel in its dry and fully swollen states, respectively,
the hydrogel behavior within this time period reflects the
mechanism of the swelling kinetic. For instance, the swelling
kinetic would be zero order if the absorption is linear. On the
other hand, the absorption occurs as a first-order kinetic if the
behavior is exponential. Generally, the absorption mechanism
changes with the cross-link content of the hydrogel. A zero-
order kinetic is favored at higher cross-link content.
1.131.5.3. Mechanical Strength
A hydrogel in its swollen state is a composite material com-
posed of solid, liquid, and air. Apparently, the extent of inter-
molecular forces within a solid is more extensive than in
the other two. Therefore, a hydrogel with more solid proper-
ties (less water and air content) is considered stronger in its
swollen state. To measure the mechanical properties, a hydro-
gel is stressed under static or dynamic loads until it fails.6,7
The testing force should be selected on the basis of actual
service conditions. For example, if the SPH is required to resist
the compressive forces, a compression test should be designed
accordingly. Similarly, if the SPH is expected to resist a dynamic
compression (compression–decompression cycles) force, an
appropriate dynamic test should be designed to evaluate the
SPH for such an application.7 For gastric retention studies,
the SPH for instance is required to not only resist the combined
forces of compression, tension, and bending altogether, but also
serve in a very harsh acidic condition. A gastric simulator, which
examines the mechanical strength of the SPH by mimicking the
real gastric conditions, has been reported.8–10 The SPHs for such
application should quickly swell up in the acidic medium of
the stomach juice to a size larger than the pyloric sphincter. The
SPH is assumed to resist the mechanical pressures inside the
stomach while it is saturated with the stomach fluid. Evaluating
and screening hydrogels that resist the real stomach pressures
have always been challenging. A texture analyzer and compres-
sive or tensile mechanical tester are normally used to evaluate
the mechanical properties of hydrogels. Although such equip-
ment can predict the comparative properties of hydrogels,
they fail to predict real mechanical properties. The simulator
generates mixed forces of compression, tension, bending, and
twisting, based on a water-hammer effect. The sample under
test will receive almost the same amount of forces throughout
its body. Finally, the stress concentrated on the weakest part of
the SPH body would result in the formation of craze, crack,
and finally disintegration of the whole platform. The simulator
can practically measure the amount of work needed to break
the hydrogel apart under real service conditions.
The swelling capacity, swelling rate, and hydrogel strength
are all ultimately dependent on the bound water and free water
within the hydrogel. Due to the lack of accuracy in measuring
the amount of water in each status, all measurements would
face a larger standard deviation. Therefore, any measuring
procedure or instrument needs to be validated to obtain
more accurate and reliable data.
1.131.6. SPH Generations
Hydrogels with fast swelling and superabsorbent properties,
different from conventional superabsorbent polymers, were
first reported by Chen et al.11 Fundamental structural and prop-
erty differences between the superabsorbent hydrogels and
superporous hydrogels have been reviewed, with an emphasis
on the evolution of SPHs and different generations of SPHs.12
Superporous hydrogels were evolved about a decade ago, and
their introduction was triggered by a need strongly felt in the
pharmaceutical area.13 There are dozens of drugs with a limited
absorption across the gastrointestinal tract, which are exten-
sively absorbed at certain areas of the GI tract such as the
upper intestine. These are called drugs with a narrow absorption
window. To increase their absorption and hence their bioavail-
ability, these drugs need to be retained in the stomach (gastric)
area for an extended period of time. There are currently a few
technologies available to increase the retention of such drugs
in the gastric medium; among them the floatable, mucoadhe-
sive, and swellable delivery systems have been studied exten-
sively. With the swellable delivery system, the drug would be
Fully swollen SPHDrySPH
4x>3x
Figure 5 Unique swelling feature of a superporous hydrogel polymer.
1st generation
Crosslink Polymer chains
Figure 6 A conventional superporous hydrogel.
Superporous Hydrogels for Drug Delivery Systems 567
accommodated in the swellable hydrogel structure and take a
very rough path to release itself from the platform by diffusion.
In this way, the drug can stay longer in the area of interest and
release itself in a more controlled manner. The early superpor-
ous hydrogels, like their superabsorbent predecessor, possessed
a very high absorption capacity and a very fast swelling rate.
These features were attractive enough for their development in
this area of application. Figure 5 shows a typical SPH, in which
its dimensions are increased to about four times the original
length in about a minute after complete swelling in water.
1.131.6.1. The First SPH Generation
A variety of monomers and polymers, as well as approaches,
have been exploited to make SPHs with different struc-
tures and properties.11,14 Among monomers, those with very
hydrophilic (e.g., carboxyl or amide in acrylic acid and acryl-
amide respectively) or ionic (e.g., carboxylate in sodium or
potassium acrylate) functions could offer superior swelling
properties. These hydrogels are generally prepared in solution
by incorporating monomers, initiators, and cross-linkers, as
well as foaming agents, into the reaction. The final product is
a superporous hydrogel with an interconnected pore structure,
which could absorb great amounts of water in a few minutes.
However, these hydrogels do not possess any mechanical
strength due to the vast number of water layers around their
hydrophilic cores. In other words, such hydrogels contain a
high proportion of free or semibound water in their swollen
state, which make them weak under mechanical pressures.
As there is no provision to increase their mechanical strength,
these hydrogels are called conventional superporous hydro-
gels. Figure 6 shows a typical synthetic procedure and structure
of the first SPH generation.
1.131.6.2. The Second SPH Generation
The need for better mechanical property triggered the develop-
ment of the second generation of SPHs or the SPH compo-
sites.15–17 These SPHs are prepared by adding a swellable filler
to the original formulation of the conventional SPHs. The swel-
lable filler is selected among pharmaceutically acceptable cross-
linked and hydrophilic polymers, including cross-linked sodium
carboxymethylcellulose (CMC), cross-linked poly(vinyl pyrro-
lidone), and cross-linked sodium starch glycolate. These are
commonly used as a superdisintegrant in the preparation of
tablets and other solid doses. The use of these in hydrogel
formulation could positively affect the SPH strength, presum-
ably due to the strengthnodsor the physical cross-links built into
the hydrogel structure (see Chapter 4.423, Polymeric Drug
Conjugates by Controlled Radical Polymerization).
1.131.6.3. The Third SPH Generation
Although the SPHs of the second generation could provide
a hydrogel with a better strength, much higher strength was
felt to be needed, for the gastric retention application in partic-
ular. This triggered the development of the third SPH genera-
tion, also called superporous hydrogel hybrids (SPHHs), with
superior mechanical properties. The primary, secondary, and
tertiary approaches have so far been disclosed. The SPH is
prepared in a conventional way, but an active material is added
during SPH synthesis, which is then treated in the ion solutions.
While the primary approach is particularly useful in making
SPHs with rubbery properties, SPHs with good mechanical
strength can be obtained by adopting the secondary approach.3
Although the mechanical properties of SPHs can be significantly
enhanced after an ion treatment, the ion compositionwas found
tobe a useful tool for better controlling the swelling andmechan-
ical properties. Depending on the activity of the ion (sodium,
calcium, aluminum, and iron in particular), any ion composition
can be used to modify and modulate SPH properties.4 Figure 7
displays the fundamental structural differences between the
second, the third, and the modified SPH generations.
SPH hybrids are prepared according to conventional SPH
formulations but a water soluble and ionogelling polymer
(synthetic or natural) is added during hydrogel preparation.
After preparation, the SPH is treated in an ion solution to
become strong and elastic.3,18 A dried SPH hybrid possesses a
folded surface morphology as shown in Figure 8. Utilizing an
ionogelling monomer in the basic monomer solution has also
been practiced to obtain improved SPH structures. For example,
a hydroxyethyl methacrylate (HEMA)-based SPH with modu-
lated swelling and mechanical property has been prepared by
2nd generation 3rd generation Modified 3rd generation
Composite orhybrid agent Crosslink 2+ Cation 3+ Cation
Figure 7 Different superporous hydrogel generations.
1 mm
Figure 8 The surface morphology of a typical superporoushydrogel hybrid.
568 Polymers
adding acrylic acid into the HEMA formulation containing a
cross-linker. After formation, the SPH foam is treated in calcium
or aluminum ions to improve the SPH strength and swelling.
It then displays stable swelling and mechanical properties in a
very harsh service environment such as gastric medium.5
1.131.6.4. Research on SPHs
By far the most common monomers used in the preparation of
SPHs are acrylic acid and acrylamide. The swelling response of
SPHs based on acrylamide and acrylic acid has been studied with
the change in the pH of the swelling medium and pressure.19,20
Solid-state NMR, swelling, density, and scanning electron
microscopy were utilized to characterize the SPH composites
of acrylamide and acrylic acid polymers cross-linked with
N,N0-methylenebisacrylamide. Apparent density and SEM
measurements showed that the SPH composites are more
porous than conventional SPHs, which results in hydrogels
with superior swelling but weaker mechanical properties.21
Due to their ionic structures, the swelling property of the
poly(acrylamide-co-acrylic acid) copolymeric SPHs are depen-
dent on the pH and ionic strength of the solution. These SPH
structures display a fast ‘on–off ’ shrinking–swelling cycle in
the pH range of 1.2 and 7.5, respectively.19 Floatable SPHs
loaded with vitamin B12 were prepared via copolymerization
of acrylamide and acrylic acid in the presence of a porogen and
a catalyst.22 The increased surface area of SPHs has been
utilized for grafting purposes. Acrylic acid could be grafted at
a high grafting efficiency on polyacrylamide gels using potas-
sium diperiodatocuprate. This feature also helps with the puri-
fication process by facilitating the mass transfer process as well
as the adsorption of ligands.23 The PEG-grafted superporous
hydrogels based on acrylic acid and acrylamide are prepared
in the presence of PEG acrylate and a foaming agent.
This modification has caused about sixfold increase in the
swelling rate.24 An amphiphilic coating based on poly(ethylene
glycol–tetramethyleneoxide) has been used to improve
the swelling kinetics of SPHs.25 The effect of acidification has
been examined on the swelling and mechanical properties of
poly(acrylamide-co-acrylic acid) SPHs. SPH swells much less in
acidic water than in distilled water. Acidification reduces
the swelling ratio but improves the mechanical properties.26
The interpenetrating network of cross-linked poly(acrylamide-
co-acrylic acid) with polyethyleneimine has also been exam-
ined.27 The effect of synthetic factors on the swelling of
superabsorbent hydrogels based on neutralized acrylic acid
and methylenebisacrylamide has been studied. The swelling
was interpreted by a Voigt-based viscoelastic model, and the
hydrogel kinetic and thermodynamic parameters were found
accordingly.28 A partially neutralized acrylic based superabsor-
bent hydrogel has been studied using different water-soluble
and oil-soluble cross-linkers and a combined porogen systemof
bicarbonate/acetone system. Highly porous gels were obtained
under conditions where the gelation period was short. Highly
cross-linked hydrogels showed almost no swelling dependence
on salt.29 SEMmorphological studies and swelling studies show
the synergistic effect of the combinedporogen systemcompared
to the use of individual gas blowing systems.30 Porous poly-
acrylamide has been synthesized using calcium carbonate
microparticles, followed by an acid treatment. The hydrogel
Relaxed 2-pointbending
Compression Tension
Figure 9 Mechanical property of a typical superporous hydrogelhybrid under various forces.
Superporous Hydrogels for Drug Delivery Systems 569
swelling is adversely affected by the calciummicroparticles and
the chemical cross-linker.31 In another study, a Taguchi experi-
mental design was used to evaluate the effect of the synthetic
variables on the gel strength of the acrylamide-based hydrogels
and superporous hydrogels.32 Poly(vinyl alcohol) has been
used to improve the strength of the SPHs based on potassium
salt of sulfopropyl acrylate, acrylic acid, and PEGdiacrylate. The
SPH is intended for gastric retention application.33 An SPH
hybrid of acrylamide and sodium alginate has been prepared
via a two-step polymerization and treatment. The process
involves polymerization and cross-linking of acrylamide in the
presence of alginate, followed by treating the prepared SPH in an
ion solution. The SPH prepared via this approach possesses
superior mechanical and elastic properties.18 The mechanical
property of the conventional SPH polymers has been improved
via network-in-network formationby including polyacrylonitrile
in the reaction.34 In another study, the gel strength of the super-
absorbent hydrogel was increased via addition of kaolin during
the hydrogel synthesis. FT-IR study confirmed the existence of
acrylic grafts on the kaolin surface. Despite an increase in gel
strength, the swelling property of the hydrogel was reduced to
a great extent. The thermal propertyof thepreparedhydrogels has
been characterized using thermal analysis including DSC and
TGA.35 Interpenetrated SPH network of poly(acrylamide-
co-acrylic acid) with chitosan and glycol chitosan was prepared.
In distilled water, both systems behave similarly but swelling
increases in acidic medium with increase in chitosan concentra-
tion. Since glycol chitosan is more hydrophilic than chitosan,
a significant increase in swelling ratewasobserved36 (seeChapter
2.213, Chitosan).
N-isopropyl acrylamide (NIPAM) and acrylamide have
been used to prepare thermosensitive SPHs with pore size of
about 100 mm. An on–off swelling–shrinking cycle is obtained
if a certain composition of the thermosensitive superabsorbent
SPH is heated up from a low (e.g., 10 �C) to a high (e.g., 65 �C)temperature.14 A higher temperature favors the hydrophobic
interactions and the polymer loses its water affinity due to a
weaker hydrophilic interaction. A temperature-sensitive poly
(NIPAM) hydrogel was prepared in an aqueous sodium chlo-
ride solution. This technique resulted in a hydrogel with sig-
nificantly higher swelling and swelling response due to the
effect of salt, which was claimed to be responsible for phase
separation and heterogeneity of the structure. These porous
hydrogels are characterized by a larger pore and smaller pore
at low and high temperature respectively, which result in com-
plete and no release of the bovine serum albumin, respec-
tively.37 Superporous hydrogel of CMC–NIPAM hydrogel was
attained via simultaneous irradiation cross-linking and addi-
tion of a foaming agent.38 Sucrose-based hydrogels and their
SPH counterparts were prepared by reacting sucrose with gly-
cidyl acrylate, followed by its polymerization. The superporous
sucrogels showed faster swelling and degradation in both
acidic and basic media.39
A combined gas-foaming and freeze-drying technique has
been used to prepare interpenetrated SPHs based on glycol
chitosan and poly(vinyl alcohol). It was shown that the num-
ber of freezing–thawing cycles has a more significant effect on
the hydrogel strength than the freezing time. A differential
scanning calorimetry was used to evaluate the thermal behavior
associated with the hydrogen bond-induced crystalline
structure of the hydrogel.40 Highly porous poly(2-hydroxyethyl
methacrylate) slabs were prepared by a simultaneous polymer-
ization and cross-linking of the HEMA monomer and ethylene
dimethacrylate. Porosity was achieved using porogens such
as cyclohexanol, dodecan-1-ol, and saccharose. Low density
values for these hydrogels indicate a closed cell rather than an
interconnected structure. Mercury porosimetry was used to eval-
uate the superporosity and microporosity status of the gels.41
Hydrofluoric acid (HF) treatment was also used to extract nano-
sized silica particles from a hydrogel matrix to make a porous
hydrogel.42
Superporous hydrogels interpenetrated with sodium
alginate have displayed pH- and salt-responsive swelling prop-
erties. Moreover, the alginate-modified SPH shows no signifi-
cant cell or mucosal damage based on thiazolyl blue, lactate
dehydrogenase assays, as well as rat’s intestine morphology.43
A fully interpenetrated superporous hydrogel with superior
mechanical and elastic properties is obtained when a synthetic
monomer is polymerized and cross-linked in the presence of a
hydrocolloid with ionogelling ability. A fully interpenetrated
network is obtained when the hydrogel is treated in an ion
solution containing calcium, iron, or aluminum.18 Figure 9
shows a typical acrylamide–alginate-based SPH hybrid in its
fully swollen state, which resists compression, bending and
tensile forces for a long period of time before it breaks apart.
Pectin has been used as a base for an intelligent superabsorbent
polymer with pH and thermosensitive swelling properties,
which can potentially be used for controlled delivery of non-
steroidal anti-flammatory drugs. Results have shown that
the drug could be delivered to the intestine without being
lost in the stomach.44
1.131.7. SPH Scale Up
Scale up is the process of preparing the SPH on a large scale.
A larger scale means an increase in the starting materials, an
increase in the container size, and dealing with a very exo-
thermic reaction on a large scale. If the synthesis of an SPH
is successful in a container with a certain geometry, it does
not necessarily mean a successful synthesis on a larger scale.
During the SPH polymerization, heat is released, which is
entrapped in the reacting mix due to the insulation property
of the pores inside the forming SPH structure. The heat buildup
can increase the rate at which normal polymerization happens,
the rate of gas formation, and also the chance of popcorn
polymerization by which cross-link density of the SPH increases
to a great extent. To release the heat from the reacting mixture,
an adequate surface should be provided, which is determined by
the aspect ratio of the container (diameter/height ratio).
570 Polymers
Dispersion of the foaming agent into the SPH formulation
during the synthesis is a typical active suspension process.
There are generally three types of suspension processes: disper-
sion of a nonreactive filler into a nonreactive medium (e.g.,
paint formulation), dispersion of a nonreactive filler into a
reacting medium (e.g., kaolin in hydrogel synthesis), and
finally, dispersion of a reactive filler into a reactive medium
(e.g., bicarbonate in SPH synthesis). Once dispersed, the bicar-
bonate particles can increase the pH by consuming the acid
component of the formulation, which in turn increases the rate
at which the redox couple would react. This in turn increases
the magnitude of the polymerization reaction and its exother-
micity. In other words, the extent of the gelling reaction would
critically depend on the amount of the bicarbonate in the
system. If not well-dispersed, a so-called ‘local hot spot’ is
produced around which a polymerization to a very high extent
is expected. This causes an undesirable heterogeneity in the
SPH structure. By far the most challenging aspect of the manu-
facture of SPHs on a large scale is the dispersion of bicarbonate
into an ongoing reaction. An SPH with a uniform pore size and
distribution is achieved if the bicarbonate is evenly dispersed
into the gelling mass. In general, the bicarbonate dispersion
within the reactingmass should be completed in a few seconds.
If not, the gelling and foaming reactions would become closely
dependent on each other and would affect progress to a great
extent. The bicarbonate can effectively be dispersed if a high-
pressure gun powder is used.45 Moreover, the mixing agitator
should have a very specific function, to be able to sweep the
bottom part of the reaction very effectively to avoid the forma-
tion of a nonporous hydrogel at the bottom of the container.
Heat buildup, and hence a faster hydrogel formation, may be
observed in areas where mixing is not effective. Another impor-
tant operational factor is the size of the bicarbonate particles.
As these particles are reactive, their reactivity would be depen-
dent on their size. As bicarbonate size decreases, its surface area
increases. This in turn increases the rate at which pH increases,
the rate at which CO2 gases are formed, and the rate of both
chemical gelling and physical foaming reactions. The corres-
ponding rates of these two critical reactions can be controlled
by selecting appropriate bicarbonate or mixing bicarbonates of
different sizes.
1.131.8. SPH Stability
In determining the stability of a given drug, adequate documen-
tation is provided to the FDA or similar organizations to prove
the identity, purity, and potency of the drug. For a superporous
hydrogel product, the same procedure should be followed.
1.131.8.1. SPH Identity
There are certain instances in which the identity of an SPH
product may change. Moisture, oxygen, ultraviolet light, and
heat are potentially the most important factors. The moisture
originates from two sources, the moisture retained in the prod-
uct, and environmental moisture. The product moisture can
be minimized by freeze drying, while the environmental mois-
ture is minimized by storing the SPH product under a dry
condition using silica gel. Although the SPH itself is also
hygroscopic, a silica gel is more effective and faster in moisture
absorption. As far as the chemical structure is concerned,
an SPH containing, for example, ester (–COO), amide
(–NHCO), and anhydride (–COOC) groups would be more
susceptible to hydrolysis.
If the SPH contains groups such as ethers (ROR0), and
aldehyde (–RCHO), it needs to be protected from oxidative
reactions. The most common way to protect the SPH from
oxygen invasion is to use different primary, secondary, and
tertiary antioxidants. Primary antioxidants such as butylated
hydroxyl anisol (BHA), butylated hydroxyl toluene (BHT),
tocopherol (vitamin E), and propyl gallate can provide electrons
to free radicals and act as free radical scavengers. Compounds
such as ascorbic acid and sodium bisulfite are secondary anti-
oxidants and can consume oxygen through autooxidation. The
last group of antioxidants, that is, tertiary antioxidants, can
react with the ions responsible for initiating the oxidation
reactions. The ion scavengers include citric acid, tartaric acid,
and ethylenediamine tetraacetic acid.
Functional groups including carbonyl (–CO–) and the
C¼C bond make a superporous hydrogel sensitive to ultravio-
let light. Theoretically, these groups may absorb light at or
greater than 280 nm. Photolysis can be prevented by storing
the SPHs in an opaque or a dark-colored container. Heat can
also change the SPH identity by expediting the hydrolytic,
oxidative, and photolytic reactions.
1.131.8.2. SPH Purity
The SPH impurities can be classified as primary, secondary, and
tertiary. Primary impurities are residual monomer, initiator,
and cross-linker left from the polymerization and cross-linking
reaction. Due to incomplete conversion of the monomer to
polymer, and incomplete inclusion of the cross-linker into the
polymer structure, unreactedmonomers and cross-linkers need
to be removed after SPH synthesis. Many researchers attempt to
find ways to reduce residual monomers, but reducing the resid-
ual initiators is also a very important consideration. Following
monomer removal, the SPH is generally washed with water and
alcohol solutions for complete purification. These two are con-
sidered secondary impurities. More water will be removed by
adding more alcohol and alcohol itself is removed by low
pressure drying. One of the very major challenges regarding
SPHs for pharmaceutical applications is that they must be
reasonably pure. Different methods have been proposed to
make a pure SPH. These include the use of low and high
glass transition monomers during the SPH synthesis and the
use of physically induced expansion and contraction in a
solvent–nonsolvent system, as well as the use of mechanical
processes such as filtration, rubbing, and centrifugation.45
The last type of impurities originate from two sources, that is,
during SPH storage and SPH service. Since water exists in the
SPH even at a very low concentration, this may result in a long-
term hydrolysis. Oxidative reactions may also proceed in a
given SPH as moisture can act as a plasticizer and facilitate the
inclusion of oxygen into the SPH structure. Generally speaking,
these reactions are associated with a change in the SPH appear-
ance and color, from snow-white to off-white or pale yellow.
During service, the SPH may face a harsh environment such as
Superporous Hydrogels for Drug Delivery Systems 571
very low acidic conditions, and so on, so its structure may be
changed or degraded, which is associatedwith the generation of
impurities. Appropriate analytical tests and methods should be
developed for a complete characterization of all types of impu-
rities within the SPH product.
1.131.8.3. SPH Potency
The SPH potency can be defined as its swelling power, which
depends on the exact amounts of the SPH and its chemical
structure. For instance, the SPH potency for a typical gastric
retention application may be defined as the amount of HCl
solution that one gram of the SPH can absorb over a certain
period of time, that is, g g�1 s�1 or ml g�1 s�1. The cross-link
density and the pore structure of the SPH can affect this factor
significantly. Although complete care needs to be taken to
purify the SPH product, increased cross-link density (physical
or chemical) may arise from other sources including polymer
crystallization, polymorph formation, entanglement, and
complexation. Polymer chains can adopt different con-
formations during long-term storage, which might affect their
swelling ability. Since the SPH is required to be compressed for
proper encapsulation, this partial pressure would increase
the intermolecular forces between the chains, by which the
swelling rate would be affected. The most common sources of
increased cross-link density are the SPH interaction with the
oppositely charged species such as calcium, aluminum, iron,
sulfate, and phosphate ions. The SPH as a final product when
it is encapsulated in an orally administrable capsule may
face another instability due to the SPH–capsule interaction
either directly or indirectly. For instance, this may happen
due to a charge difference between the SPH structure and the
structure of the capsule or due to the interaction between
the ions within the SPH structure and the capsule material,
which results in polymer–polymer interchain complexation
and ion–polymer complexation, respectively.
Although the SPH potency should not theoretically be cor-
related to the amount of pore, the pore can affect both the SPH
swelling capacity and its rate. Since the SPH product is soft in
general, and the pores are embedded into a soft SPH matrix,
their shape and size can be changed upon application of minor
pressures. Pores not only provide capillary action to the water
diffusion process, but they also increase the contact surface
area with the aqueous medium. Any change in the shape
and size of the pores would imbalance the swelling–pore
correlation. As SPHs for oral delivery are required to be
encapsulated, the original size of the SPH needs to be reduced
in order to fit the capsule size. This compression effect appar-
ently affects the SPH pore structure, which might affect the
ultimate swelling property of the SPH. A swelling–compression
correlation has been found, whose magnitude depends on the
orientation of the SPH during compression. In other words,
the original noncompressed SPH swelling is preserved if the
SPH is compressed along the gas movement line which is from
the bottom to the top. Compression force applied in the oppo-
site direction severely affects the swelling kinetic of an SPH.20
The SEM and swelling studies displayed that the swelling
kinetics of the SPH is not affected by the surface morphology
and surface porosity measured via mercury porositometry.
Studies show that SPH swelling is predominantly determined
by the internal SPH structure.1
From the biopharmaceutics perspective, the SPH may lose
its potency due to interaction with foods or beverages. Fatty
foods, oils, and materials of such nature may reduce the SPH
potency by making the swelling environment more lypophilic.
On the other hand, more basic or more acidic juices as well as
salts may also affect the SPH potency to a lesser or greater
extent. If the SPH is ionic in nature, its potency would dramati-
cally be reduced by increasing the ionic strength of the swelling
medium. The effect of different beverages on the swelling behav-
ior of multiple SPH formulations has been studied for gastric
retention applications.46
1.131.9. SPH Safety
The SPHmay be considered safe if it does not affect the human
body either chemically or physically. To be considered chemi-
cally safe, the SPH should contain less than tolerated amounts
of residual materials. This requires developing a very effective
purification process and very accurate analytical methods. The
SPH is considered physically safe if its administration does not
pose any threat to the human body. One of the most serious
concerns in administrating a swellable material is esophagus
obstruction. Due to its rapid water absorption, a naked SPH
may absorb water in the esophagus area, become expanded
and hence obstruct the area. This can be avoided by using
proper encapsulation materials and methods. Multiple SPH
doses may be administered to ensure that esophagus obstruc-
tion does not occur under severe and aggressive conditions.
Another aspect of an SPH dosage form is its chemical inter-
action with the stomach acids. For instance, an ester-based
superporous hydrogel is susceptible to ester hydrolysis under
severe acidic conditions in the stomach, in particular under
long-fasting gastric conditions. An adequate number of studies
should be conducted to ensure that there are no, or only safe,
by products of such a reaction. In the preparation of SPHs and
their dosage form for human clinical studies, care must be
taken to use materials with nonanimal origin, which require
a TSE (transmissible spongiform encephalopathy) certificate
for every starting material.
1.131.10. SPH Platform Design for Drug Delivery
To deliver a drug via a swellable platform, the drug needs to be
incorporated into the SPH platform. The drug is first formu-
lated into a drug delivery system (DDS) and the DDS is then
incorporated into the SPH platform. Although many designs
are possible, two designs have been practiced for gastric reten-
tion and peroral intestinal delivery of different drugs. Depend-
ing on the position of the DDS with respect to the SPH
platform, these may be called internal DDS and external DDS
designs as shown in Figure 10. In the former, the DDS is placed
in the center of the SPH platform and is held in place using
an SPH plug. The SPH plug is also held in place by gluing
it onto the SPH body from the top. The whole platform
is then encapsulated inside an orally administrable capsule.
SPH plug Adhesive
DDS
SPH body
External DDSInternal DDS
Figure 10 Different platform designs for the superporous-hydrogel-based drug delivery.
572 Polymers
Upon administration and the exposure of the capsule to
the stomach acid (for gastric retention), the capsule is dis-
solved and the SPH platform would be exposed to the gastric
contents. This results in an immediate expansion of the SPH to
its full extent, which is followed by drug release by diffu-
sion.47–50 In the external DDS approach, the SPH is attached
externally to the SPH body using biocompatible glue, and the
platform is then encapsulated in an oral capsule. For peroral
intestinal delivery, the capsule itself is enterically coated to
prevent the capsule and the SPH from premature dissolution
or swelling in the gastric medium. Upon entering the intestine
area, the higher pH favors capsule dissolution, which is fol-
lowed by SPH expansion. The SPHwould expand to a size large
enough to dock itself into the intestinal wall. The drug is then
released directly through the intestinal cells.51–53
1.131.11. SPH in Drug Delivery and Other Areas
SPHs were originally intended for prolonging retention
of drugs with a narrow window of absorption. In designing
a superporous hydrogel for such applications, one needs to
consider the drug–SPH interaction, which is caused by interac-
tion of their functional groups. Drugs such as acetohydroxamic
acid (AHA),54 repaglinide,56 metoclopramide,57,58 and amoxi-
cillin59,60 contain amide groups. Amine groups can be found
in drugs such as acyclovir,61 amoxicillin, cefuroxime axetil,62
furosemide,63 gabapentin,64 levodopa,65–67 metformin HCl,68
metoclopramide, ranitidine HCl,69 and famotidine.70 The
carboxyl groups are part of amoxicillin, ciprofloxacin,71 furo-
semide, gabapentin, ibuprofen,57 levodopa, and repaglinide-
can structures. All these drugs have been examined for gastric
retention applications via different methods. From a compati-
bility perspective, SPHs containing ion may not be a good
choice to prolong the gastric retention of levodopa or gabapen-
tine, which contain carboxyl groups. SPHs containing carboxyl
groups may interact via hydrogen bonding with the drugs con-
taining carboxyl and amine groups. SPHs, due to their moisture
content, may expedite the hydrolysis of amide-containing drugs
during storage. SPH compatibility with other excipients used to
make the DDS also requires careful evaluation.
1.131.11.1. Gastric Retention
A holy grail in oral drug delivery is to develop a dosage form
with the ability to control drug release for a relatively long
period of time. Besides floating and mucoadhesion concepts, a
swelling concept has also been exploited to extend the residence
time of the drugs with a narrow absorption window.47,49,72–75
Following the discovery of Helicobacter pylori, a need for an
efficient dosage form with the ability to remain in the gastric
medium was also felt. A gastroretentive platform needs to be
designed based on a good knowledge of physiological factors
and biopharmaceutical aspects of the gastric medium.76 The
SPH design for gastric retention applications has been the sub-
ject of several articles.15,77,78
Gastric retention requires the swellable platform to stay in
the gastric medium for a reasonable period of time, that is, a
few hours after dose administration. The mechanism by which
a platform would stay in the gastric medium is by swelling, and
this requires the SPH to swell to a size larger than the pylorus
diameter. Assuming an average pylorus diameter of 1.5–2 cm,
at least two out of three dimensions of the hydrogel should be
larger than 2 cm. On the other hand, the platform needs to be
administered orally using a conventional capsule for human
administration. Generally, a 00 gelatin or HPMC capsule with
an outer diameter of 8.53mm, height of 23.30mm, and vol-
ume of 0.95ml is used. A simple calculation shows that a
swellable hydrogel for such an application should expand in
the gastric medium to at least 2.3 times its original dimension,
or to at least 12 times its original volume. The required rate at
which a swellable hydrogel should expand is dependent on
many factors, which affect gastric emptying. For example, if the
stomach contains only water, it takes about 25min to have half
of the consumed water depleted from the stomach. This is
a good assumption to design a platform with a desirable swell-
ability. The hydrogel would face a premature depletion from
the stomach if it cannot swell to its maximum size in less than
25min. In order to stay integrated in the gastric medium for a
desirable period of time, the SPH should resist gastric contrac-
tion and expansion forces, which are maximized during the
housekeeping period of the phase III stomach motility. By far,
this is the most challenging part in designing SPHs for such
applications. The maximum volume that the SPH can acquire
in its dry state is about 0.95ml for encapsulation into, for
example, a 00 gelatin capsule. Depending on the drug loading
capacity, a certain volume of the SPH is occupied by the drug or
the DDS. In other words, the effective capsule volume occu-
pied by the SPH would be around 0.6ml. With the SPH having
a density of 1 gml�1, the maximum feasible weight of the SPH
inside the capsule would be around 0.6 g. The calculation
shows that the SPH in its fully swollen state would contain
about 95wt% of water. Ironically, a hydrogel which contains
5% of solid and 95% of water should resist the very aggressive
stomach forces, which requires significant intermolecular
forces within the swollen SPH structure to preserve the SPH
integrity in such conditions. Moreover, the SPH needs to pos-
sess all these required properties under a very low pH condi-
tion of the stomach. The SPH screened for such application
also requires to be very safe chemically and physically, and this
needs to be proved first in animals. As far as its efficacy is
concerned, the proof of gastric retention can be first conducted
Superporous Hydrogels for Drug Delivery Systems 573
in animal models, but for many reasons the results would not
necessarily prove the concept in humans. Since no animal has
proved to be a reliable model for such studies, the proof of
gastric retention would at best be confirmed by conducting a
small-scale study in humans.
One of the most important considerations in using swella-
ble platforms for gastric retention is the SPH–DDS interaction.
Two studies have been conducted in which the drug model
was formulated into a wax and a solid based delivery system.
In both studies, the dissolution was performed in a USPII
paddle type apparatus using 900ml of 0.01N HCl (pH 2.0)
at 37� 0.2 �C and 100 rpm. An HP8453 UV/VIS was used to
measure the absorbance of the drug model at 280nm. Differ-
ent formulations were prepared by including amodel drug into
a low (Gelucire) and high (Compritol) molecular weight
wax.50,79 The amount of drug loaded into the wax system was
about 20wt%. An HPMC capsule was used to encapsulate both
the wax and the wax-loaded SPH. The study showed that the
same amount of drug is released from the wax system and
the SPH–wax system when a low melting wax was used as the
delivery system. On the other hand, a prolonged release was
observed over a much longer period of time for the higher
melting wax system. Apparently, as shown in Figure 11, the
low melting wax is removed from the SPH system at the disso-
lution temperature of 37 �C, while the majority of the high
melting wax still remains over the same retention time (i.e.,
48 h) in the dissolution medium. With the latter, the SPH
pores are presumably blocked by the wax, which results in a
much slower drug release.
In another study, a delivery system with a drug loading of
75wt% was designed using the combination of a fast dissol-
ving polymer (polyvinyl pyrrolidone) and a slow dissolving
polymer (hydroxypropyl methylcellulose) at different ratios.80
While the pure drug model was released from the SPH in less
than 30min, the delivery system containing higher HPMC
contents showed an extended release over a much longer
Gelucire Campritol
Wax residue
Figure 11 Superporous hydrogel with wax-based delivery systems.
period of time resembling a zero-order kinetic at the highest
HPMC/PVP ratio as shown in Figure 12. These observations
may be accounted for in terms of the solubility behavior of the
two polymers. As the PVP is very water soluble, it can be
dissolved in water even when only a small amount of water is
available. On the other hand, a complete dissolution of HPMC
requires muchmore water to be freely available to the polymer.
When a tablet containing HPMC is enclosed within the SPH
platform, the HPMC, due to the lack of water availability,
produces a very thick gelatinous mass inside the SPH. This
causes the drug to experience a much longer path for its com-
plete release from the platform.
The proof of the gastric retention principle for various SPH
hybrids has been studied in swine. The study showed that an
acrylate–chitosan hybrid could provide a minimum of 24h
retention in the swine stomach under different fed and fasted
conditions.81,82 The safety and toxicity of different hydrogel
formulations have been studied for gastric retention applica-
tions.83 SPH retention in man has been studied using scintig-
raphy. SPHs radiolabeled with 99Tc were encapsulated in an
enteric-coated gelatin capsule and administered orally.84 In a
study on SPHs based on chitosan and glycol chitosan for
gastric retention application, it was found that the swelling
property of the glycol chitosan is superior to that of chitosan
alone.85 Superporous hydrogel of (acrylic acid-co-acrylamide)/
O-carboxymethyl chitosan has been evaluated for oral insulin
delivery. Followed by insulin loading and release, the circular
dichroism (CD) spectra indicated a stable insulin conforma-
tion as well as its bioactivity according to hypoglycemic effect
in mice. The hydrogel could bind to Ca2þ and entrap enzymes,
which resulted in inactivation of trypsin and a-chymotrypsin.
Results of this study showed a significant hypoglycemic effect
for insulin loaded into the SPH and better bioavailability
compared to subcutaneous insulin injection.86 Another study
with the same polymer indicated a physical interaction between
the polymer and insulin.87 The polymer was also examined for
its cytotoxicity and genotoxicity. The study showed that the SPH
caused minimal damage to cell viability, lysosomal activity, and
metabolic activity. A study on mice showed that the SPH
which contains minute amounts of monomer and cross-linker,
is truly biocompatible and can be considered a safe carrier for
protein delivery.88 Glycol chitosan SPHs were prepared and
loaded with dispersed and conjugated amoxicillin to treat the
00
20
40
60
80
100
5 10Time (h)
0.14Puredrug
Dru
g re
leas
ed (%
) 1.28 10.4
15 20
Figure 12 Drug release from superporous hydrogel with solid-baseddelivery systems.
574 Polymers
H. pylori. A prolonged drug delivery effect was observed for the
conjugated system whose release mechanism was due to hydro-
lysis as opposed to diffusion for the dispersed drug.89
SPH particlesGrinderSPH slab
Molding Single SPH dose
Figure 13 Manufacturing superporous hydrogels for variousapplications.
1.131.11.2. Peroral Intestinal Delivery
Conventional and composite generations of SPHs have been
widely studied for peroral peptide and protein administra-
tion.90 The CSPHs and SPHCs were evaluated for enhancing
the drug transport (different molecular weights) across the
porcine intestine (in vitro study).51 Among the factors studied
were the possible damage to intestinal cells, the ability of SPH
for mechanical fixation, the SPH effect on paracellular drug
permeability, and cytotoxicity in Caco-2 monolayers.91 The
release behavior of peptides such as buserelin, octreotide, and
insulin,92 the intestinal in vitro absorption of desmopressin,93
and the mechanism of paracellular tight junction opening in
the Caco-2 cells94 have also been studied. Due to improved
mechanical properties, in vitro mucoadhesion forces and load-
ing capability, hydrogels based on acrylic acid-co-acrylamide
andO-carboxymethyl chitosan have been proposed as a poten-
tial mucoadhesive system for peroral delivery of proteins and
peptides.95
1.131.11.3. SPHs as Diet Aid
A highly swelling SPH with gastric retention ability can be
designed to occupy a large portion of the stomach volume to
induce fullness in humans. To achieve a sense of fullness, a
minimum of 400ml of the stomach volume should presumably
be occupied by the SPH. If a pure SPH with no drug or DDS is
used for this application, around 0.6 g of the SPH can be housed
in a 00 capsule as mentioned before. To be effective in such
application, a single 0.6 g dose of SPH should have a potency of
at least 650ml g�1. Using conventional materials and techni-
ques, this potency can hardly be achieved under very low acidic
conditions of the stomach. Therefore, the application requires
the use of multiple doses of SPH to achieve adequate volume,
which brings more safety risks as related to the impurities and
physical esophagus obstruction. Moreover, water itself due to
the high concentration (minimum of 650ml) should also be
studied as a control to see if it can induce any fullness effect at
such concentration. Potentially, an SPH platform as a diet aid
may be formulated with other excipients to achieve its maxi-
mum potency. These may include excipients to adjust stomach
pH or relax stomach motility.
1.131.11.4. SPHs as Superdisintegrant
Superdisintegrants are pharmaceutically acceptable polymers
based on cellulose, poly(vinyl pyrrolidone), and starch deriva-
tives, which have a tailor-made swelling property. These are
supplied in particle form and mixed into a solid dosage formu-
lation to offer a desirable disintegration. The SPHs are also
cross-linked hydrophilic polymers, whose swelling capacity
and rate can be tailored for such applications. Nonetheless,
there are issues that need to be addressed before the use of SPH
particles can be justified. For gastric retention, intestinal reten-
tion, and diet application, the SPH is produced and used as a
single platform, generally in a cylindrical shape as shown in
Figure 13. The SPH particulates on the other hand can be
produced in powder form by grinding the SPH slabs using
appropriate equipment or can be produced directly in particle
form by an inverse dispersion technique. With the grinding
technique, which is cost effective and commercially more
attractive, the most challenging issue would be to keep the
production environment as dry as possible. The SPH dust can
sit and make a gel coat on almost any piece of equipment
during processing. A major difference between the SPH super-
disintegrant and conventional superdisintegrants is that the
former can provide a much larger surface due to its size and
its pore content. In one study, the SPH particles, in particular
those based on poly(acrylic acid) were used as a wicking agent
in the formulation of fast-disintegrating tablets.96
1.131.11.5. Other Applications
Sodium CMC and hydroxyethyl cellulose cross-linked with
divinyl sulphone have been used to remove body fluids during
surgery and to collect body fluids in the treatment of edema.
The polymer biocompatibility is also promising in diuretic
therapy.97,98 Sodium CMC and hydroxyethyl cellulose as well
as poly(ethylene glycols) of different molecular weights have
been used in developing orally administrable hydrogels for
water absorption.98 High capacity super water absorbents were
injected intracerebrally for studying hypothalamic areas in
controlling the female production cycle.99 The SPH micro-
spheres were used in the clinical evaluation of transcatheter
arterial embolization for hypervascular metastatic bone
tumor.100 In another biomedical application, freeze-dried
water absorbents were used to design plugs and haemostatic
and other medical devices.101 These were also used in compact
and light-weight bags102 and in surgical drapes103 to manage
body fluids. As the core for wound dressing, the polyacrylate
water absorbents could retain microorganisms and reduce the
number of viable germs.104 Hydrogels based on sodium acry-
late, N-vinyl pyrrolidone, and silver were also studied for their
antibacterial activity105 (see Chapter 1.122, Structural Biomed-
ical Polymers (Nondegradable)).
In cell scaffolding, PEG diacrylate has been studied for cell
infiltration and vascularization.106 To be used as a support for
Superporous Hydrogels for Drug Delivery Systems 575
cell cultivation, an SPH based onHEMA and ethylene dimetha-
crylate has been prepared. The porosity of the structure was
achieved via a salt-leaching technique using sodium chloride
and ammonium persulfate. Different techniques including
SEM, mercury porositometry, and dynamic desorption of nitro-
gen were used to characterize the hydrogels.107 A hydrogel with
goodmechanical properties to function with a healthy cartilage,
yet porous to allow tissue integration, is very much needed for
articular cartilage repair. Such a potential material has been
prepared using poly(vinyl alcohol) and poly(vinyl pyrrolidone)
through a double emulsion process followed by a freezing–
thawing process.108 Superporous hydrogels have the potential
to be used as scaffold for cell transplantation. A highly
interconnected poly(ethylene glycol) diacrylate with macro-
pores in the range of 100–600 mmhas shown a rapid cell uptake
and cell seeding.109 The SPH formulation containing hydroxy-
apatite as filler can potentially be used as scaffold in bone tissue
engineering due to improved mechanical strength.110 Different
techniques including FTIR, SEM/EDX, and cytocompatibility
using L929 fibroblasts were utilized to characterize the prepared
SPHs. A photo-cross-linking reaction and a foaming process
have been utilized in developing a PEG-based superporous
hydrogel with high pore interconnectivity. This feature is essen-
tial for applications such as tissue engineering where tissue
invasion and nutrient transport are basic requirements.111
Kroupova et al. have shown that SPHs have the potential to
initiate the differentiation of embryonic stein (ES) cells112 (see
Chapter 1.132, Dynamic Hydrogels).
1.131.12. Conclusions
Due to their hydrophilic, cross-linked, and porous structure,
SPH polymers display a swelling behavior different from that
of conventional water swelling hydrogels. This feature has been
utilized in developing swellable platforms for drug delivery
applications. SPHs have been studied for prolonging the reten-
tion of drugs with a narrow window of absorption, and for
peroral intestinal absorption of peptide and protein drugs.
The feasibility of SPHs in pharmaceutical applications relies
on many factors, including its scale up, safety, and stability.
This chapter discusses the basic concepts in developing a syn-
thetic swellable platform for certain pharmaceutical and bio-
medical applications.
References
1. Gemeinhart, R. A.; Park, H.; Park, K. Polym. Adv. Technol. 2000, 11, 617–625.2. Chaterjia, S.; Kwon, K.; Park, K. Prog. Polym. Sci. 2007, 32, 1083–1122.3. Omidian, H.; Qiu, Y.; Yang, S. C.; Kim, D.; Park, H.; Park, K. U.S. Pat. 6,960,617,
2005.4. Omidian, H.; Rocca, J. G. U.S. Pat. 7,056,957, 2006.5. Omidian, H.; Rocca, J. G. U.S. Pat. Applic. 20080089940, 2008.6. Omidian, H.; Park, K.; Rocca, J. G. J. Pharm. Pharmacol. 2007, 59, 317–327.7. Han, W.; Omidian, H.; Rocca, J. G. Dynamic Swelling of Superporous Hydrogels
Under Compression; American Association of Pharmaceutical Scientists (AAPS):Tennessee, USA, 2005.
8. Gavrilas, C.; Omidian, H.; Rocca, J. G. Dynamic mechanical properties ofsuperporous hydrogels. In 8th US–Japan Symposium on Drug Delivery Systems,HI, 2005.
9. Gavrilas, C.; Omidian, H.; Rocca, J. G. A novel gastric simulator. In The 32ndAnnual Meeting of the Controlled Release Society (CRS), Miami, FL, 2005.
10. Gavrilas, C.; Omidian, H.; Rocca, J. G. A novel simulator to evaluate fatigueproperties of superporous hydrogels. In 8th US–Japan Symposium on DrugDelivery Systems, HI, 2005.
11. Chen, J.; Park, H.; Park, K. J. Biomed. Mater. Res. 1999, 44, 53–62.12. Omidian, H.; Rocca, J. G.; Park, K. J. Control. Release 2005, 102, 3–12.13. Park, K.; Park, H. U.S. Pat. 5,750,585, 1998.14. Chen, J.; Park, K. J. Macromol. Sci. Pure Appl. Chem. 1999, A36, 917–930.15. Chen, J.; Park, K. J. Control. Release 2000, 65, 73–82.16. Park, K.; Chen, J.; Park, H. U.S. Pat. 6,271,278, 2001.17. Park, K.; Chen, J.; Park, H. Superporous hydrogel composites: A new generation
of hydrogels with fast swelling kinetics, high swelling ratio and high mechanicalstrength. In Polymeric Drugs and Drug Delivery systems; Ottenbrite, R.,Kim, S. W., Eds.; CRC Press: Boca Raton, FL, 2001.
18. Omidian, H.; Rocca, J. G.; Park, K. Macromol. Biosci. 2006, 6, 703–710.19. Gemeinhart, R. A.; Chen, J.; Park, H.; Park, K. J. Biomater. Sci. Polym. Ed. 2000,
11, 1371–1380.20. Gemeinhart, R. A.; Park, H.; Park, K. J. Biomed. Mater. Res. 2001,
55, 54–62.21. Dorkoosh, F. A.; Brussee, J.; Verhoef, J. C.; Borchard, G.; Rafiee-Tehrani, M.;
Junginger, H. E. Polymer 2000, 41, 8213–8220.22. Bajpai, S. K.; Bajpai, M.; Sharma, L. Iran. Polym. J. 2007, 16, 521–527.23. Savina, I. N.; Mattiasson, B.; Galaev, I. Y. Polymer 2005, 46, 9596–9603.24. Huh, K. M.; Baek, N.; Park, K. J. Bioact. Compat. Polym. 2005, 20, 231–243.25. Baek, N.; Park, K.; Park, J. H.; Bae, Y. H. J. Bioact. Compat. Polym. 2001,
16, 47–57.26. Kim, D.; Seo, K.; Park, K. J. Biomater. Sci. Polym. Ed. 2004, 15, 189–199.27. Kim, D.; Park, K. Polymer 2004, 45, 189–196.28. Kabiri, K.; Omidian, H.; Hashemi, S. A.; Zohuriaan-Mehr, M. J. J. Polym. Mater.
2003, 20, 17–22.29. Kabiri, K.; Omidian, H.; Hashemi, S. A.; Zohuriaan-Mehr, M. J. Eur. Polym. J.
2003, 39, 1341–1348.30. Kabiri, K.; Omidian, H.; Zohuriaan-Mehr, M. J. Polym. Int. 2003, 52,
1158–1164.31. Mahdavinia, G. R.; Mousavi, S. B.; Karimi, F.; Marandi, G. B.; Garabaghi, H.;
Shahabvand, S. Express Polym. Lett. 2009, 3, 279–285.32. Omidian, H.; Park, K. J. Bioact. Compat. Polym. 2002, 17(6), 433–450.33. Yang, S.; Park, K.; Rocca, J. G. J. Bioact. Compat. Polym. 2004, 19, 81–100.34. Qiu, Y.; Park, K. AAPS Pharm. Sci. Tech. 2003, 4, E51.35. Kabiri, K.; Zohuriaan-Mehr, M. J. Polym. Adv. Technol. 2003, 14, 438–444.36. Seo, K. W.; Kim, D. J.; Park, K. N. J. Ind. Eng. Chem. 2004, 10, 794–800.37. Cheng, S. X.; Zhang, J. T.; Zhuo, R. X. J. Biomed. Mater. Res. A 2003, 67A,
96–103.38. Abd El-Rehim, H. A.; Hegazy, E. S. A.; Diaa, D. A. J. Macromol. Sci. Pure Appl.
Chem. 2006, A43, 101–113.39. Chen, J.; Park, K. Carbohydr. Polym. 2000, 41, 259–268.40. Park, H.; Kim, D. J. Biomed. Mater. Res. A 2006, 78A, 662–667.41. Hradil, J.; Horak, D. React. Funct. Polym. 2005, 62, 1–9.42. Kaneko, T.; Asoh, T. A.; Akashi, M. Macromol. Chem. Phys. 2005, 206,
566–574.43. Yin, L. C.; Fei, L. K.; Tang, C.; Yin, C. H. Polym. Int. 2007, 56, 1563–1571.44. Pourjavadi, A.; Barzegar, S. Starch-Starke 2009, 61, 161–172.45. Omidian, H.; Gavrilas, C.; Han, W.; Li, G.; Rocca, J. G. U.S. Pat. Applic.
20080206339, 2008.46. Li, G.; Omidian, H.; Rocca, J. G. Solvent Effects on the Swelling Properties of
Superporous Hydrogels; American Association of Pharmaceutical Scientists(AAPS): Tennessee, USA, 2005.
47. Rocca, J. G.; Omidian, H.; Shah, K. Controlled release of compounds mediated byretention in the upper part of the GI tract. In The 30th Annual Meeting andExposition of the Controlled Release Society (CRS), Glasgow, Scotland, 2003.
48. Rocca, J. G.; Omidian, H.; Shah, K. Business Briefing Pharmatech. 2003,152–156.
49. Rocca, J. G.; Omidian, H.; Shah, K. Drug Deliv. Technol. 2005, 5, 40–46.50. Rocca, J. G.; Shah, K.; Omidian, H. Gattefosse Tech. Bull. 2004, 97, 73–84.51. Dorkoosh, F. A.; Borchard, G.; Refiee-Tehrani, M.; Verhoef, J. C.; Junginger, H. E.
Eur. J. Pharm. Biopharm. 2002, 53, 161–166.52. Dorkoosh, F. A.; Verhoef, J. C.; Borchard, G.; Rafiee-Tehrani, M.; Junginger, H. E.
J. Control. Release 2001, 71, 307–318.53. Dorkoosh, F. A.; Verhoef, J. C.; Verheijden, J. H. M.; Refiee-Tehrani, M.;
Borchard, G.; Junginger, H. E. Pharm. Res. 2002, 19, 1532.54. Umamaheswari, R. B.; Jain, S.; Tripathi, P. K.; Agrawal, G. P.; Jain, N. K. Drug
Deliv. 2002, 9, 223–231.55. Fukuda, M.; Peppas, N. A.; Mcginity, J. W. J. Control. Release 2006, 115,
121–129.
576 Polymers
56. Rokhade, A. P.; Patil, S. A.; Belhekar, A. A.; Halligudi, S. B.; Aminabhavi, T. M.J. Appl. Polym. Sci. 2007, 105, 2764–2771.
57. Tang, Y. D.; Venkatraman, S. S.; Boey, F. Y. C.; Wang, L. W. Int. J. Pharm. 2007,336, 159–165.
58. Singh, S.; Singh, J.; Muthu, M. S.; Balasubramaniam, J.; Mishra, B. Curr. Drug.Deliv. 2007, 4, 269–275.
59. Torrado, S.; Prada, P.; de la Torre, P. M.; Torrado, S. Biomaterials 2004, 25,917–923.
60. Rajinikanth, P. S.; Balasubramaniam, J.; Mishra, B. Int. J. Pharm. 2007, 335,114–122.
61. Groning, R.; Berntgen, M.; Georgarakis, M. Eur. J. Pharm. Biopharm. 1998, 46,285–291.
62. Dhumal, R. S.; Rajmane, S. T.; Dhumal, S. T.; Pawar, A. P. J. Sci. Ind. Res. 2006,65, 812–816.
63. Sakkinen, M.; Tuononen, T.; Jurjenson, H.; Veski, P.; Marvola, M. Eur. J. Pharm.Sci. 2003, 19, 345–353.
64. Gabapentin extended-release – Depomed: Gabapentin ER, gabapentin gastricretention, gapapentin GR. Drugs R D 2007, 8(5), 317–320.
65. Goole, J.; Deleuze, P.; Vanderbist, F.; Amighi, K. Eur. J. Pharm. Biopharm. 2008,68, 310–318.
66. Klausner, E. A.; Eyal, S.; Lavy, E.; Friedman, M.; Hoffman, A. J. Control. Release2003, 88, 117–126.
67. Hoffman, A.; Stepensky, D.; Lavy, E.; Eyal, S.; Klausner, E.; Friedman, M.Int. J. Pharm. 2004, 277, 141–153.
68. Metformin extended release – DepoMed: Metformin, metformin gastric retention,metformin GR. Drugs R D 2004, 5(4), 231–233.
69. Hassan, M. A. J. Drug Deliv. Sci. Technol. 2007, 17, 125–128.70. Jaimini, M.; Rana, A. C.; Tanwar, Y. S. Curr. Drug Deliv. 2007,
4, 51–55.71. Varshosaz, J.; Tavakoli, N.; Roozbahani, F. Drug Deliv. 2006, 13, 277–285.72. Davis, S. S. Drug Discov. Today 2005, 10, 249–257.73. Davis, S. S.; Wilding, E. A.; Wilding, I. R. Int. J. Pharm. 1993, 94, 235–238.74. Hwang, S. J.; Park, H.; Park, K. Crit. Rev. Ther. Drug Carrier Syst. 1998, 15,
243–284.75. Streubel, A.; Siepmann, J.; Bodmeier, R. Curr. Opin. Pharmacol. 2006, 6,
501–508.76. Bardonnet, P. L.; Faivre, V.; Pugh, W. J.; Piffaretti, J. C.; Falson, F. J. Control.
Release 2006, 111, 1–18.77. Chen, J.; Blevins, W. E.; Park, H.; Park, K. J. Control. Release 2000,
64, 39–51.78. Bajpai, S. K.; Bajpai, M.; Sharma, L. J. Macromol. Sci. Pure Appl. Chem.
2006, A43, 507–524.79. Li, G.; Omidian, H.; Rocca, J. G. Wax-loaded superporous hydrogel platforms.
In The 32nd Annual Meeting of the Controlled Release Society (CRS), Miami, FL,2005.
80. Han, W.; Omidian, H.; Rocca, J. G. A novel acrylate ester-based superporoushydrogel. In The 32nd Annual Meeting of the Controlled Release Society (CRS),Miami, FL, 2005.
81. Han, W.; Omidian, H.; Rocca, J. G. In Vivo and In Vitro Studies on NovelGastroretentive Superporous Hydrogel (SPH) Platforms; American Association ofPharmaceutical Scientists (AAPS): Salt Lake City, Utah, USA, 2003.
82. Han, W.; Omidian, H.; Rocca, J. G. Evaluation of gastroretentive superporoushydrogel platforms using swine model. In The 31st Annual Meeting of theControlled Release Society (CRS), Honolulu, HI, 2004.
83. Townsend, R.; Rocca, J. G.; Omidian, H. Safety and toxicity studies of a novelgastroretentive platform administered orally in a swine emesis model. InThe 32nd Annual Meeting of the Controlled Release Society (CRS),Miami, FL, 2005.
84. Dorkoosh, F. A.; Stokkel, M. P. M.; Blok, D.; et al. J. Control. Release 2004, 99,199–206.
85. Park, H.; Park, K.; Kim, D. J. Biomed. Mater. Res. 2006, 76A, 144–150.86. Yin, L. C.; Ding, J. Y.; Fei, L. K.; et al. Int. J. Pharm. 2008,
350, 220–229.87. Yin, L. C.; Zhao, Z. M.; Hu, Y. Z.; et al. J. Appl. Polym. Sci. 2008, 108,
1238–1248.88. Yin, L.; Zhao, X.; Cui, L.; et al. Food Chem. Toxicol. 2009, 47, 1139–1145.89. Park, J.; Kim, D. J. Biomater. Sci. Polym. Ed. 2009, 20, 853–862.90. Dorkoosh, F. A.; Verhoef, J. C.; Borchard, G.; Refiee-Tehrani, M.; Junginger, H. E.
J. Control. Release 2001, 71, 307–318.91. Dorkoosh, F. A.; Setyaningsih, D.; Borchard, G.; Refiee-Tehrani, M.;
Verhoef, J. C.; Junginger, H. E. Int. J. Pharm. 2002, 241, 35–45.92. Dorkoosh, F. A.; Verhoef, J. C.; Ambagts, M. H. C.; Refiee-Tehrani, M.;
Borchard, G.; Junginger, H. E. Eur. J. Pharm. Sci. 2002, 15, 433–439.93. Polnok, A.; Verhoef, J. C.; Borchard, G.; Sarisuta, N.; Junginger, H. E. Int.
J. Pharm. 2004, 269, 303–310.94. Dorkoosh, F. A.; Broekhuizen, C. A. N.; Borchard, G.; Rafiee-Tehrani, M.;
Verhoef, J. C.; Junginger, H. E. J. Pharm. Sci. 2004, 93, 743–752.95. Yin, L. C.; Fei, L. K.; Cui, F. Y.; Tang, C.; Yin, C. H. Biomaterials 2007, 28,
1258–1266.96. Yang, S. C.; Fu, Y. R.; Hoon, S.; Park, J. K.; Park, K. J. Pharm. Pharmacol. 2004,
56, 429–436.97. Sannino, A.; Esposito, A.; de Rosa, A.; Cozzolino, A.; Ambrosio, L.; Nicolais, L.
J. Biomed. Mater. Res. A 2003, 67A, 1016–1024.98. Esposito, A.; Sannino, A.; Cozzolino, A.; et al. Biomaterials 2005, 26,
4101–4110.99. Ohta, M.; Homma, K. Gen. Comp. Endocrinol. 1988, 72, 424–430.100. Ken’ichiro, H.; Katsuyuki, N.; Munehito, S.; et al. Clin. Orthop. Surg. 2004,
39(10), 1307–1314.101. Sawhney, A. S.; Bennett, S. L.; Pai, S. S.; Sershen, S. R.; Co, F. H.
U.S. Pat. Applic. 2007/0231366, 2007.102. Ohta, T.; Kuroiwa, T. Surg. Neurol. 1999, 51, 464–465.103. Tankerseley, T. N. U.S. Pat. 2007/0135784, 2007.104. Bruggisser, R. J. Wound Care 2005, 14, 438–442.105. Lee, W. F.; Huang, Y. C. J. Appl. Polym. Sci. 2007, 106, 1992–1999.106. Keskar, V.; Gandhi, M.; Gemeinhart, E. J.; Gemeinhart, R. A.; Keskar, V. J. Tissue
Eng. Regen. Med. 2009, 3, 486–490.107. Horak, D.; Hlidkova, H.; Hradil, J.; Lapcikova, M.; Slouf, M. Polymer 2008, 49,
2046–2054.108. Spiller, K. L.; Laurencin, S. J.; Charlton, D.; Maher, S. A.; Lowman, A. M. Acta
Biomater. 2008, 4, 17–25.109. Keskar, V.; Marion, N. W.; Mao, J. J.; Gemeinhart, R. A. Tissue Eng. Part A 2009,
15, 1695–1707.110. Tolga Demirtas, T.; Karakecili, A. G.; Gumusderelioglu, M. J. Mater. Sci. Mater.
Med. 2008, 19, 729–735.111. Sannino, A.; Netti, P. A.; Madaghiele, M.; et al. J. Biomed. Mater. Res. A 2006,
79A, 229–236.112. Kroupova, J.; Horak, D.; Pachernik, J.; Dvorak, P.; Slouf, M. J. Biomed. Mater.
Res. B Appl. Biomater. 2006, 76B, 315–325.
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